Distribution of dendritic spines and inhibitory inputs on layer 2 and layer 3 pyramidal neurons of the anterior cingulate cortex

Gilman, Joshua Paul

22 January 2016

The anterior cingulate cortex (ACC) plays an important role in reward-based decision-making, linking higher-order thinking and emotions. Because of this area's dense connectivity it is important to study the properties of the excitatory and inhibitory network that governs ACC output. The aim of this study was to characterize the morphology of dendritic excitatory postsynaptic sites and inhibitory inputs on layer 2 and layer 3 ACC pyramidal neurons, the principal intracortical projection neurons of the cortex. Using biocytin-filling and high-resolution confocal imaging, we quantified the distribution of dendritic spines, the major sites of excitatory input, on pyramidal cells. We visualized inhibitory inputs apposed to specific pyramidal cell compartments, including the axon initial segment, soma, dendrites, and dendritic spines, through immunohistochemical labeling of vesicular γ-aminobutyric acid transporter. Layer 2 and layer 3 cells had similar spine densities on their apical and basal dendritic compartments, with a maximum spine density occurring in their middle apical and middle basal compartments. Axon initial segments of layer 3 cells had a higher density of inhibitory input compared to the layer 2 cells (0.84 vs 0.66 apps/μm). The apical dendritic shaft had a higher apposition density than the basal dendritic shaft in an individual layer (layer 2, 0.50 vs 0.32; layer 3, 0.50 vs 0.28 apps/μm) with the majority of the innervation occurring on the proximal compartments of both apical and basal segments. Although located in different laminae, these cells showed similar inhibitory input distributions, with higher amounts of inhibition proximally. Finally, these inhibitory inputs also occurred on dendritic spines, with the highest density on thin spines. However, proportionally, mushroom spines had the highest level of innervation, with up to 44% of these spines receiving inhibitory input. These findings add to the understanding of how inhibition at the cellular level can affect the output of the ACC and begin to uncover important relationships between cellular structure and function in this brain region.

Neurosciences

Cingulate

Inhibition

Spines

Aspects of thorn development on Prosopis juliflora (Swartz) DC. var. velutina (Woot.) Sarg. and Cercidium australe I. M. Johnson

Karpiscak, Martin M.

January 1973

No description available.

Thorns.

Spines (Botany)

Mesquite.

PUNCTURE PERFORMANCE OF THE CAUDAL SPINES FROM TWO COASTAL STINGRAYS, HYPANUS SAY AND HYPANUS SABINUS

Unknown Date

A diagnostic characteristic of stingrays in the Family Dasyatidae is the presence of a defensive, partially-serrated spine located on the tail. The objective of this study is to assess the impacts of caudal spine morphology on puncture and withdrawal performance from two stingrays, Hypanus sabinus and Hypanus say. Spines have highly variable morphology. I used an Instron E1000 materials tester to quantify the puncture and withdraw forces from porcine skin, a model for human skin. I found no significant differences between puncture and withdraw or between the species. By incorporating micro-CT scanning to quantify mineralization density, I quantified more mineralization along the shaft of the spine. Equal puncture and withdraw forces and increased mineralization along the spine shaft may create a stiffer structure that can be a persistent predator deterrent. / Includes bibliography. / Thesis (M.S.)--Florida Atlantic University, 2020. / FAU Electronic Theses and Dissertations Collection

Stingrays

Dasyatidae

Spines (Zoology)

The Rapid Effects of GPER on Learning and Memory and Dendritic Spines in Female Mice

Gabor, Christopher

17 May 2013

Estrogen receptor (ER) involvement through genomic mechanisms have been well established in different aspects of cognition and neuronal plasticity. However, much less is known about the rapid, non-genomic effects on these processes. G-protein coupled estrogen receptor (GPER) is a relatively recently discovered estrogen receptor that has previously been shown to affect learning and memory on a long term genomic timescale. This thesis investigated the rapid effects of the GPER selective agonist G-1 on four estrogen-sensitive learning paradigms: social recognition, object recognition, object placement and social transmission of food preferences (STFP) paradigm. The rapid effects of G-1 on neuronal plasticity were also examined through changes in hippocampal dendritic spine length and density. Results show that GPER activation may rapidly enhance social recognition, object recognition and object placement learning while may impair social learning in the STFP paradigm. G-1 treatment also resulted in increases of dendritic spine density in the stratum radiatum of the CA1 hippocampus. This suggests that GPER, along with the classical ERs, mediates the rapid effects of estrogen on learning and neuronal plasticity. Thus, GPER may be a viable target for enhancing cognitive function in estrogen related therapies.

Learning

Memory

Dendritic Spines

Estrogen

Diabetes exacerbates the loss of basilar dendritic spines after ischemic stroke

Sweetnam Holmes, Andrew

09 January 2014

Most stroke survivors recover some degree of lost function after an ischemic event. Recovery however, is negatively affected by comorbid conditions such as diabetes. Successful recovery is dependent on the ability of adjacent surviving cortical tissue and functionally related areas to take over functions lost by the stroke. Recently our lab has shown that diabetes interferes with the remapping of sensory function to peri-infarct areas after photothrombotic stroke. Given this result, it is crucial to understand how diabetes affects the structure of neurons following stroke, particularly at the level of dendritic spines, which receive the vast majority of excitatory synaptic inputs. Type I diabetes was pharmacologically induced in transgenic mice expressing yellow fluorescent protein (YFP) in a subset of cortical neurons 4 weeks prior to receiving unilateral photothrombotic stroke in the forelimb area of the primary somatosensory cortex (FLS1). Spine density measurements were made on the apical and basilar dendrites of layer-5 pyramidal neurons at 1 and 6 weeks after stroke. Our analysis indicated that diabetes was associated with fewer apical and basilar dendritic spines in the peri-infarct region 1 week after stroke. At 6 weeks of recovery, peri-infarct dendritic spine density in both control and diabetic animals returned to baseline levels. These changes were specific to the peri-infarct cortex, as spine density in distant cortical areas such as the forelimb sensorimotor region of the contralateral hemisphere, were not affected by stroke. In order to relate changes in spine density to the recovery of forepaw function, we re-analyzed data from a previous study that employed the forepaw adhesive-tape-removal test (Sweetnam et al 2012). This analysis revealed that diabetes significantly increased the latency of tape removal from the impaired forepaw (when normalized to the unaffected paw) at 1 but not 6 weeks of recovery. Collectively, these findings indicate that diabetes exacerbates forepaw impairments and basilar spine loss initially after stroke, but does not affect the ability of the brain to replace lost spines over weeks of recovery. / Graduate / 0317

plasticity

dendritic spines

Stroke

behaviour

Pathological upregulation of a calcium-stimulated phosphatase, calcineurin, in two models of neuronal injury

Kurz, Jonathan Elledge,

January 1900

Thesis (Ph.D.)--Virginia Commonwealth University, 2006. / Title from title-page of electronic thesis. Prepared for: Dept. of Pharmacology & Toxicology. Bibliography: leaves [190]-207.

CREB Induces Structural Changes in LA Neurons making them more Advantageous for Inclusion into the Fear Memory Trace

Higgs, Gemma Victoria

27 November 2013

The current study aimed to determine the selective advantage of lateral amygdala (LA) neurons overexpressing the transcription factor CREB that enables their preferential incorporation into the fear memory trace. I hypothesized that overexpression of CREB drives the formation of dendritic spines, potentially providing these neurons with greater connectivity to sensory inputs at the time of learning. Using viral-mediated gene transfer, CREB tagged with GFP, or GFP as a control, was overexpressed in the LA of wild-type mice. Spine number and morphology were compared in homecage mice at the time when mice are normally trained in fear conditioning. Spine density was increased in neurons with CREB vector compared to neurons with GFP vector whereas spine head diameter and length was not different. Therefore, LA neurons overexpressing CREB have increased spine number at the time of learning, potentially providing these neurons with a selective advantage for incorporation into the fear memory trace.

Transcription factor

Dendritic spines

Fear memory

0317

CREB Induces Structural Changes in LA Neurons making them more Advantageous for Inclusion into the Fear Memory Trace

Higgs, Gemma Victoria

27 November 2013

The current study aimed to determine the selective advantage of lateral amygdala (LA) neurons overexpressing the transcription factor CREB that enables their preferential incorporation into the fear memory trace. I hypothesized that overexpression of CREB drives the formation of dendritic spines, potentially providing these neurons with greater connectivity to sensory inputs at the time of learning. Using viral-mediated gene transfer, CREB tagged with GFP, or GFP as a control, was overexpressed in the LA of wild-type mice. Spine number and morphology were compared in homecage mice at the time when mice are normally trained in fear conditioning. Spine density was increased in neurons with CREB vector compared to neurons with GFP vector whereas spine head diameter and length was not different. Therefore, LA neurons overexpressing CREB have increased spine number at the time of learning, potentially providing these neurons with a selective advantage for incorporation into the fear memory trace.

Transcription factor

Dendritic spines

Fear memory

0317

Age and growth estimates for the Port Jackson shark, Heterodontus portusjacksoni, (Meyer, 1793) from New South Wales, Australia

Ramos, Robert

January 2007

Research Doctorate - Doctor of Philosophy (PhD) / World shark populations are declining rapidly from the increased demand for shark meat and fins and from their capture as by-catch. Techniques to accurately and reliably estimate the age of elasmobranchs are required to understand life history and develop management strategies. Although some biological information exists for the harvested species, few of the many shark species caught as by-catch have been investigated. In the waters of New South Wales, Australia, the Port Jackson shark (Heterodontus portusjacksoni) is a non-targeted species, however it is a major contributor to the elasmobranch by-catch in the bottom trawl and prawn fisheries. Although some biological and ecological information exists on Port Jackson sharks from New South Wales, there is no understanding of suitable techniques to age this species and of the age structure of the New South Wales’ population. Hence, the main purpose for the present study was to determine a suitable technique to age Port Jackson sharks and thereby provide essential age and growth data for its future management, sustainable use and conservation. This study consisted of research into: (1) the macroscopic anatomy of the vertebral centra and dorsal spines from 652 H. portusjacksoni to explore their suitability as ageing structures; (2) a comparison of whole and sectioned vertebral centra and of whole and sectioned dorsal spines for ageing; (3) validation of the annual formation of growth bands; (4) a comparison of the effect of prior experience on readers’ ability to count annual growth bands in vertebral centra; and (5) the development of age-growth models for the New South Wales’ population of H. portusjacksoni. Two types of vertebral centra (trunk and caudal vertebrae) were found in the vertebral column. Both vertebrae consisted of a centrum, 2 ribs, 4 neural arches, basiopophyses and neural foramen and decreased in size from anterior to posterior. A strong linear relationship was identified between vertebral diameter (VD) and fork length (FL). Each dorsal spine was positioned anterior to the dorsal fin and consisted of a stem and the cap. A strong linear relationships were identified between spine base width (SBW) and FL. The existence of alternating opaque and translucent band pairs in both structures further suggested they may be suitable for ageing purposes. Validation (calcein and oxytetracycline injections, marginal increment analysis, and centrum edge analysis) confirmed that translucent band pairs were formed during the winter (September-November) and were annual in both vertebral centra and dorsal spines. Whole and sectioned vertebral centra and dorsal spines were individually examined to determine which method best estimated the age. Although both methods had individual low reading bias and high precision, there was a difference between the two methods. The average bias between the two methods using vertebral centra was -0.158 ±0.05 and the coefficient of variance (CV) was 92.32% for females and -0.157 ±0.03 and CV was 56.95% for males. This indicated that sectioned vertebral centra returned higher ages than whole vertebral centra. When comparing whole dorsal spine age estimates to sectioned dorsal spines, there was an average bias between methods of -0.22 ±0.026 and a low precision 73.09%. Again indicating that sectioned dorsal spines returned higher ages than whole dorsal spines. A comparison of ages estimated from sectioned vertebral centra and sectioned dorsal spines showed that vertebral centra aged older than dorsal spines. Although the two structures each had low reading bias and high reading precision, there were differences between the two structures. The average bias between the two structures was -0.4 ±0.03 and the CV was low (74.7%), indicating that there was a significant difference in age derived from the two structures. Therefore, great caution should be taken when choosing which structure to use for age estimation. Ages of sharks estimated from the recommended sectioned vertebral centra ranged from 0.2 to 32.5 years for females and 0.2 to 23.8 years for males. Four different growth models were compared using both sectioned vertebral centra and sectioned dorsal spines to estimate the best suitable growth curve. Out of the 4 growth models the Gompertz Growth Function (GGF) best described the growth of H. portusjacksoni. von Bertalanffy growth parameters estimated from ageing data using the GGF for females were t0 = 2.584 yr, k = 0.111, L∞ = 1134.1 mm FL, and for males t0 = 1.629 yr, k = 0.131, L∞ = 1012.9 mm FL. This indicates that H. portusjacksoni has a slow growth rate and a longer life span than most other elasmobranch species. The effect of reader’s experience on the bias and precision of age estimates of sectioned vertebral centra was determined in an experiment that compared the author (an experienced vertebral centra reader) with an experienced fish otolith reader, two readers recently trained in reading vertebral centra (but lacking experience), and two untrained and inexperienced readers. Bias and precision were determined for each reader from two ageing trials with the same structure three months apart. Between-trials bias for each reader (except the author)ranged from 0.033 to 0.13 and precision ranged from 8.2 to 19.5%, while the author had low bias 0.006 and high precision 1.1%. When comparing all the readers with the author, bias ranged from 0.033 to 0.13 with an 8.2 to 19.5% precision for trial one, and 0.017 to 0.5 with precision between 2.5 to 5.4% in trial two. The age-bias plots comparing the two trials all indicated that only the author was consistent. And the age-bias plots between the author and the other readers all indicated that neither experience in ageing teleost otoliths or limited training in ageing enhanced the bias or precision compared to inexperienced elasmobranch agers.

sharks

Port Jackson sharks

vertebrae

dorsal spines

Age and growth estimates for the Port Jackson shark, Heterodontus portusjacksoni, (Meyer, 1793) from New South Wales, Australia

Ramos, Robert

January 2007

Research Doctorate - Doctor of Philosophy (PhD) / World shark populations are declining rapidly from the increased demand for shark meat and fins and from their capture as by-catch. Techniques to accurately and reliably estimate the age of elasmobranchs are required to understand life history and develop management strategies. Although some biological information exists for the harvested species, few of the many shark species caught as by-catch have been investigated. In the waters of New South Wales, Australia, the Port Jackson shark (Heterodontus portusjacksoni) is a non-targeted species, however it is a major contributor to the elasmobranch by-catch in the bottom trawl and prawn fisheries. Although some biological and ecological information exists on Port Jackson sharks from New South Wales, there is no understanding of suitable techniques to age this species and of the age structure of the New South Wales’ population. Hence, the main purpose for the present study was to determine a suitable technique to age Port Jackson sharks and thereby provide essential age and growth data for its future management, sustainable use and conservation. This study consisted of research into: (1) the macroscopic anatomy of the vertebral centra and dorsal spines from 652 H. portusjacksoni to explore their suitability as ageing structures; (2) a comparison of whole and sectioned vertebral centra and of whole and sectioned dorsal spines for ageing; (3) validation of the annual formation of growth bands; (4) a comparison of the effect of prior experience on readers’ ability to count annual growth bands in vertebral centra; and (5) the development of age-growth models for the New South Wales’ population of H. portusjacksoni. Two types of vertebral centra (trunk and caudal vertebrae) were found in the vertebral column. Both vertebrae consisted of a centrum, 2 ribs, 4 neural arches, basiopophyses and neural foramen and decreased in size from anterior to posterior. A strong linear relationship was identified between vertebral diameter (VD) and fork length (FL). Each dorsal spine was positioned anterior to the dorsal fin and consisted of a stem and the cap. A strong linear relationships were identified between spine base width (SBW) and FL. The existence of alternating opaque and translucent band pairs in both structures further suggested they may be suitable for ageing purposes. Validation (calcein and oxytetracycline injections, marginal increment analysis, and centrum edge analysis) confirmed that translucent band pairs were formed during the winter (September-November) and were annual in both vertebral centra and dorsal spines. Whole and sectioned vertebral centra and dorsal spines were individually examined to determine which method best estimated the age. Although both methods had individual low reading bias and high precision, there was a difference between the two methods. The average bias between the two methods using vertebral centra was -0.158 ±0.05 and the coefficient of variance (CV) was 92.32% for females and -0.157 ±0.03 and CV was 56.95% for males. This indicated that sectioned vertebral centra returned higher ages than whole vertebral centra. When comparing whole dorsal spine age estimates to sectioned dorsal spines, there was an average bias between methods of -0.22 ±0.026 and a low precision 73.09%. Again indicating that sectioned dorsal spines returned higher ages than whole dorsal spines. A comparison of ages estimated from sectioned vertebral centra and sectioned dorsal spines showed that vertebral centra aged older than dorsal spines. Although the two structures each had low reading bias and high reading precision, there were differences between the two structures. The average bias between the two structures was -0.4 ±0.03 and the CV was low (74.7%), indicating that there was a significant difference in age derived from the two structures. Therefore, great caution should be taken when choosing which structure to use for age estimation. Ages of sharks estimated from the recommended sectioned vertebral centra ranged from 0.2 to 32.5 years for females and 0.2 to 23.8 years for males. Four different growth models were compared using both sectioned vertebral centra and sectioned dorsal spines to estimate the best suitable growth curve. Out of the 4 growth models the Gompertz Growth Function (GGF) best described the growth of H. portusjacksoni. von Bertalanffy growth parameters estimated from ageing data using the GGF for females were t0 = 2.584 yr, k = 0.111, L∞ = 1134.1 mm FL, and for males t0 = 1.629 yr, k = 0.131, L∞ = 1012.9 mm FL. This indicates that H. portusjacksoni has a slow growth rate and a longer life span than most other elasmobranch species. The effect of reader’s experience on the bias and precision of age estimates of sectioned vertebral centra was determined in an experiment that compared the author (an experienced vertebral centra reader) with an experienced fish otolith reader, two readers recently trained in reading vertebral centra (but lacking experience), and two untrained and inexperienced readers. Bias and precision were determined for each reader from two ageing trials with the same structure three months apart. Between-trials bias for each reader (except the author)ranged from 0.033 to 0.13 and precision ranged from 8.2 to 19.5%, while the author had low bias 0.006 and high precision 1.1%. When comparing all the readers with the author, bias ranged from 0.033 to 0.13 with an 8.2 to 19.5% precision for trial one, and 0.017 to 0.5 with precision between 2.5 to 5.4% in trial two. The age-bias plots comparing the two trials all indicated that only the author was consistent. And the age-bias plots between the author and the other readers all indicated that neither experience in ageing teleost otoliths or limited training in ageing enhanced the bias or precision compared to inexperienced elasmobranch agers.

sharks

Port Jackson sharks

vertebrae

dorsal spines